DE2941943C2 - - Google Patents

Description

The invention relates to a Record carrier in which information in an optical readable information structure is attached that from information areas arranged in information tracks exists in the lane direction through intermediate areas are separated from each other, with the information traces are separated from each other by intermediate tracks and where the information area has a phase depth of approximately 180 °, is almost constant over the entire record carrier.

One such is in U.S. Patent No. 3,931,459 Record carriers as a medium for transmission described a color television program. The radiation-permeable Information structure comes with a readout bundle read that from one lens system to one Selection spot in the size of the information areas is focused. That modulated by the information structure Readout bundle is on a radiation sensitive Information detection system focused. The information structure can be a phase structure weighted with an amplitude be considered, d. H. that when reading this Structure of the difference between the phases of the different parts originating from the record carrier of the readout bundle as a function of that at the moment read out part of the information structure varies. At  interfere with the location of the information detection system the different bundle parts together so that the intensity that caught by the information detection system Radiation and thus the output signal of this detection system depending on the currently read out Information varies.

The information areas of an optical Record carrier can be made in the record carrier surface pressed pits or from over this surface protruding humps exist. The information structure can also be a radiation-reflecting one instead of a radiation-permeable one Structure.

When reading out the information structure is this with a readout in the order of magnitude Information areas exposed and it can can be understood as a diffraction pattern that the Read light beams split into a number of spectral orders. These orders can have a certain phase and a certain one Amplitude can be awarded. The "phase depth" will than the difference between the phases of the zero spectral Order and the first spectral orders defined, if the center of the readout spot is in the middle of an information area coincides.

When reading out the record carrier care must be taken to ensure that the center of the readout spot always with the middle of the currently read track part coincides because otherwise the modulation depth of the read signal is small and crosstalk between neighboring tracks can occur. Therefore, when reading out derived a tracking signal that is an indication of the location of the readout spot with respect to the center of the instantaneous read track part there. This signal will fed to a servo system, with the help of the location of the Readout spots can be readjusted.  

As described in U.S. Patent No. 3,931,459 is, the tracking signal with the help of two radiation-sensitive Detectors are generated in the distant Field of the information structure on both sides of a line are arranged that are effectively parallel to the track direction runs. If the center of the readout spot is centered the track coincides, the two detectors receive an equal amount of radiation. If the middle of the readout spot towards the middle of a currently read Track part is displaced, receives, depending on the direction the shift, one of the detectors a bigger one Amount of radiation than the other. This detection method, where the difference in intensity between two by different Bundle parts passing through the pupil halves is determined, is referred to as "push pull" detection. The pupil is the exit pupil of a lens system, that is between the record carrier and the detectors located. If the tracking signal derived in this way should be optimal, according to US-PS No. 39 31 459 the "phase difference" defined there is the same an odd multiple of 90 °. The phase difference is the difference between the phases a bundle part originating from an information area and the phase of the environment of this information area originating bundle part defined. This phase difference is generally of that defined above Phase depth different. Only if the phase difference Is 180 ° and the walls of the information areas are vertical Walls, the phase difference is equal to the phase depth. A phase difference of 90 ° does not correspond to one Phase depth of 90 °, but corresponds, depending on u. a. the breadth of the information areas, a phase depth of e.g. B. 115 °.

When the information itself is read out should be that the change in intensity of the total Radiation passing through the pupil is detected (the so-called "Contral aperture" detection),  a phase depth of 115 ° is not optimal.

The present invention has the task to create a record carrier that when reading both an optimal information signal and an optimal one Provides tracking signal. This object is achieved with the features of claim 1.

While in previously proposed record carriers the information areas at the same time as Servo areas for positioning the reading spot in relation to the middle of a track part currently read out served, form in the now proposed record carrier the intermediate areas the servo areas. The phase depth of the information areas now has the value that for the "central aperture" reading of the information is optimal is, while the phase depth of the intermediate areas is the relative has a low value for generation of the tracking signal via "push pull" reading optimal is. It is essential that the phase depth of the intermediate areas is so small that when it is read out in the "Central aperture "mode these areas a negligible deliver small signal.  

With the now preferably used Enrollment procedures can use the intermediate areas with the small Phase depth almost in the form of pits or humps with weak inclinations, i.e. with large inclination angles, be realized.

A preferred embodiment of a Record carrier according to the invention with a radiation reflecting Information structure is therefore characterized by that the phase depth of the intermediate areas is one Value between about 100 ° and about 110 ° that the Intermediate areas are essentially V-shaped that the Tilt angle between the walls the intermediate areas and a normal on the record carrier a value from the range of 80 ° to 85 °.

The intermediate areas can theoretically have a V-shape with acute angles. In practice but the intermediate areas are rather inclined pits or be hump. These intermediate areas show no flat ground or peaks on how the information areas. The phase depth of the intermediate areas becomes essentially determined by the steepness of the wall of these areas. The limits, within which the phase depth can change are narrow, so that the limits within which the The angle of inclination of the intermediate areas can change accordingly are tight. The optimal value within the stated limits for the angle of inclination is from the readout bundle used dependent. The optimal angle of inclination when used of a readout bundle supplied by a helium-neon laser differs by a few degrees from the optimal one Inclination angle when using an AlGaAs diode laser.  

A record carrier according to the invention, which is intended with a He-Ne readout bundle to be left out is characterized in that the Track width is about 625 nm, and that the phase depth of the intermediate areas is about 100 ° and that the angle of inclination of the walls of the intermediate areas is about 84 °.

Better than reading out with one Readout bundle, which is supplied by a He-Ne laser, is suitable considering the influence of the intermediate areas a record carrier on the information signal according to the invention, read out with a readout bundle to be that of a semiconductor diode laser, specifically an AlGaAs diode laser, which has one wavelength in the range of about 780 nm to about 860 nm.

An advantageous record carrier according to the invention, which is intended to be read out with a readout bundle to be supplied by an AlGaAs diode laser is characterized in that the track width  is about 625 nm, and that the phase depth of the intermediate areas 100 ° and the angle of inclination of the walls of the intermediate areas is about 82 °.

When reading with one of an AlGaAs Diode lasers delivered during the "Central aperture" mode hardly noticed the intermediate areas.

The for different record carriers specified values for the inclination angle apply to the Transitions between the intermediate areas and the intermediate tracks.

The present invention can be not just in a record carrier that is completely with information is provided, but also in a record carrier apply, in which the user himself still information can enroll. In such a record carrier is the information address information and in the so-called sector addresses, of which a certain one Number per track are available. The sector addresses occupy only a small part of the tracks. The track parts between the sector addresses consist of a writable Material, e.g. B. a thin metal layer in which the  Users, e.g. B. with the help of a laser beam, information can enroll, e.g. B. in that the metal locally is melted. In a sector address there is address information the associated writable track part in the form of address areas attached by each other Intermediate areas are separated. The address areas point according to the invention a greater phase depth than the intermediate areas.

Some embodiments of the invention are shown in the drawings and are described below described in more detail. It shows

Fig. 1 shows a part of the information structure of a round disc-shaped record carrier,

Fig. 2 shows a part of a tangential section through a preferred embodiment of a record carrier according to the invention,

Fig. 3 shows a first radial section through part of a preferred embodiment of a record carrier according to the invention,

Fig. 4 shows a second radial section through part of a preferred embodiment of a record carrier according to the invention,

Fig. 5 is a known device for reading a record carrier,

Fig. 6, the cuts in the far field of the information structure by the first zero-order subbeam and by sub-beam systems,

Fig. 7 shows the variation of the amplitude of the information signal and the tracking signal as a function of the phase depth, and

Fig. 8 is a record carrier in which the user can write information himself.

As shown in FIG. 1, the information structure consists of a number of information areas 2 , which are arranged in information tracks 3 . The information areas are separated from one another by intermediate areas 4 in the track direction or the tangential direction t. The tracks 3 are separated from one another in the radial direction r by intermediate tracks 5 . The information areas can consist of pits pressed into the surface of the record carrier or of protrusions protruding beyond the record carrier surface. The distance between the bottom of the pits or the top of the hump and the level of the intermediate tracks is basically constant, as is the width of the information areas and the intermediate areas at the level of the level of the intermediate tracks. The distance and width mentioned are not determined by the information stored in the structure.

The information stored in the record carrier is defined in the change in the area structure in only the tangential direction. If a color television program is stored in the record carrier, the luminance signal can be coded in the change in the spatial frequency of the information areas 2 and the color type and sound signal in the change in the lengths of the areas 2 . Instead of a television program, the recording medium can also contain an audio program. The information can also be digital information. Then a certain combination of information areas 2 and intermediate areas 4 represents a certain combination of digital ones and zeros.

Such a record carrier with a radiation-reflecting information structure can be read out using a device which is shown schematically in FIG. 5. One of a gas laser 10 , e.g. B. a helium-neon laser, emitted monochromatic and linearly polarized beam 11 is reflected by a mirror 13 to a lens system 14 . An auxiliary lens 12 is arranged in the path of the radiation beam 11 and ensures that the pupil of the objective system 14 is filled. A diffraction-limited readout spot V is then generated on the information structure. The information structure is shown schematically by tracks 3 ; the record carrier is thus shown in radial section.

The information structure can be located on the side of the recording medium facing the laser. However, as is shown in FIG. 5, the information structure is preferably located on the side of the recording medium facing away from the laser, so that reading is carried out through the transparent substrate 8 of the recording medium. This has the advantage that the information structure is protected from fingerprints, dust particles and scratches.

The readout bundle 11 is reflected by the information structure and, when the record carrier rotates, is modulated in a track that is currently read out by means of a disk 16 driven by a motor 15 in accordance with the order of the information areas 2 and the intermediate areas 4 . The modulated readout bundle again passes through the lens system 14 and is reflected by the mirror 13 . In order to separate the modulated readout bundle from the unmodulated readout bundle, a polarization-sensitive partial prism 17 and a λ₀ / 4 plate 18 (where λ₀ represents the wavelength in the free space of the readout bundle) are preferably arranged in the radiation path. The bundle 11 is transmitted from the prism 17 to the λ₀ / 4 plate 18 , which converts the linearly polarized radiation into circularly polarized radiation which is incident on the information structure. The reflected readout beam passes through the λ₀ / 4 plate 18 again , the circularly polarized radiation being converted into linearly polarized radiation, the polarization plane of which is rotated through 90 ° with respect to the radiation emitted by the laser 10 . As a result, the readout beam will be reflected during the second passage through the prism 17 , specifically to a radiation-sensitive detection system 19 . This system consists of two detectors 20 and 21 , the dividing line effectively running parallel to the track direction. The signals from the detectors 20 and 21 are fed to the circuit 22 , in which the signals are added to one another. The output signal S of this circuit is modulated in accordance with the information currently read out. On the other hand, the signals from the detectors 20 and 21 are fed to the circuit 23 , in which the signals are subtracted from one another. The output signal S _{r of} the circuit 23 gives an indication of the size and the direction of a position error of the readout spot with respect to the center of the track currently being read out. This signal can be processed in the circuit 24 in a manner known per se to form a control signal for readjusting the position of the readout spot, e.g. B. in that the mirror 13 is tilted about the axis 25 .

Now it will be demonstrated why the specified values for the phase depth of the information areas and the intermediate areas are optimal values. Here For the sake of simplicity, it is assumed that the information areas and the intermediate areas have vertical walls.

The information structure is exposed with a readout spot V, the dimension of which is in the order of magnitude of the dimensions of the information areas and intermediate areas, and can be regarded as a diffraction pattern which divides the readout beam into an undeflected sub-beam of zero spectral order, a number of sub-beams of first spectral orders and a number of Sub-bundles of higher spectral orders splits. The numerical aperture of the lens system and the wavelength of the readout beam are adapted to the information structure in such a way that the sub-beams of higher orders largely fall outside the pupil of the lens system and do not reach the detection system 19 . In addition, the amplitudes of the sub-bundles of higher orders are small compared to the amplitudes of the sub-bundle of zero order and the sub-bundles of first orders.

In addition to the sub-bundles b (+1.0) and b (-1.0) deflected in the track direction, sub-bundles b (0, + 1) and b (0, -1) also arise, which are transverse to the track direction, thus in the direction of arrow 41 in Fig. 6, are deflected. In this figure, the cross sections of the sub-bundle b (0, + 1) and b (0, -1) with the circle 36 with the center 37 and with the circle 38 with the center 39 are indicated. These sub-bundles interfere at the locations of the detectors 20 and 21 with the zero-order sub-bundle b (0,0). If it is assumed for the sake of simplicity that the tracks are continuous grooves with a phase depth ψ₂, the phase Φ (0, + 1) or Φ (0, -1) of the sub-bundle b (0, + 1) or b (0, -1) with respect to sub-bundle b (0,0) can be represented by

where Δr represents the distance between the center of the readout spot and the center of the track and q represents the radial period of the track structure (cf. FIG. 1). The position-dependent output signals of the detectors 20 and 21 can be represented by

S₂₀ = C (ψ₂) · cos (ψ₂ + 2 π Δ r / q)

S₂₁ = C (ψ₂) · cos (ψ₂ - 2 π Δ r / q),

where C (ψ₂) is an information-independent quantity that is a function of the phase depth ψ₂. For ψ₂ = 90 ° C (ψ₂) can be set to zero. The difference signal or "push pull" signal S _r is then

S _r = -2 C (ψ₂) · sin ψ₂ · sin 2 π Δ r / q.

The component sin 2 π Δr / q is an odd function of Δr, so that the signal S _{r contains} information about the size and direction of a position error of the readout spot with respect to the center of the track.

It can be demonstrated that the amplitude, C (ψ₂) sin ψ₂, of the "push pull" signal S _r is maximum for ψ₂ = 115 °. This then applies to areas with vertical walls. For areas with sloping walls, the expression for S _{r is} different and more complex than that given above. The course of the amplitude A _Sr , as a function of the phase depth ψ₂, for areas with sloping walls is indicated in Fig. 7 with the dashed curve 44 . The maximum for the amplitude is reached for a phase depth ψ₂ = 110 °. If the intermediate areas in a record carrier according to the invention have a phase depth of ψ₂ = 110 °, an optimal tracking signal is obtained.

As can be seen from FIG. 7, areas with a phase depth of 110 ° will deliver a small but not negligible signal even with a “central aperture” reading. This means that the modulation depth of the information signal S _i decreases somewhat. This effect can be improved by making the phase depth ψ₂ of the intermediate regions smaller. Preferably ψ₂ = 100 °. Areas with such a phase depth provide a negligible signal with "Central aperture" reading, while with "Pushpull" reading the signal S _r with respect to the signal S _r , which is obtained at a phase depth ψ₂ = 110 °, decreases only slightly .

The phase depth values given above ψ₂, 115 ° for intermediate areas with vertical walls and 100 ° for intermediate areas with sloping walls no critical values. With small deviations from these Adequate reading remains possible.

As already mentioned, they are Intermediate areas preferably V-shaped. To the one you want To get phase depth, the angle of inclination must be between 80 ° and 85 °. The geometry of the intermediate areas is then pretty much determined. The influence of the selection bundle on the optimal structure of the intermediate areas low. The optimal value ψ₂ = 100 ° is used of a He-Ne laser beam, with λ₀ = 633 nm, at an angle of inclination of 84 ° reached while this value is applied of an AlGaAs laser, with λ₀ between 780 nm and 860 nm, with an inclination angle of 82 °. The polarization state of the readout bundle exerts with "Pushpull" - Reading a little influence on the perceived Phase depth of the intermediate areas.  

The article "Laser beam recording of videomaster disks" in "Applied Optics", Volume 17, No. 13, pp. 2001-2006 describes how the information areas can be registered. A photoresist layer applied to a substrate is exposed with a laser beam, the intensity of which is switched between a high level and a low level in accordance with the information to be written. After the registration, the photoresist is developed, pits being formed in the areas exposed to high radiation intensity. The intermediate areas in the record carrier according to the invention can be obtained in that the intensity of the write-in bundle between a high level and a less high level, e.g. B. in the order of 40% to 60% of the high level is switched. During development, the deeper information pits 2 are formed at the locations that are exposed to a high radiation intensity, and the less deep intermediate pits 4 are created at the locations that are exposed to a lower radiation intensity.

Simply because of the intensity distribution within the registered bundle used the final record carrier has sloping walls. The development process also influences the steepness of the wall: The steepness of the wall decreases depending on the development time to.  

In Fig. 2 a small part of a preferred embodiment of a recording medium according to the invention in tangential section along the line II-II 'in Fig. 1 is shown, while in Fig. 3 a first radial section, along the line III-III' in Fig. 1, and in Fig. 4, a second radial section, along the line IV-IV 'in Fig. 1, is shown. When reading out, the record carrier is exposed from the underside, the substrate 8 being used as an optical protective layer. The information structure can be provided with a layer 6 made of highly reflective material, e.g. B. silver, aluminum or titanium coated. A protective layer 7 can also be applied on the layer 6 , which protects the information structure from mechanical damage, such as scratches.

"Pushpull" readings can be different Inclinations of the intermediate areas can be distinguished.  The angle of inclination R₂ is also within narrower Limits.

It can still be noticed be that at an angle of inclination R₂ = 85 ° preferably a perpendicularly polarized bundle is used while at a tilt angle of 80 ° a parallel polarized or a circularly polarized bundle is used can be.

So far it has been assumed that the information structure is a radiation reflecting structure. However, the invention can also be used with a radiation-permeable recording medium. The detection system 19 is then arranged on a different side of the record carrier than the radiation source. In this case too, the phase depth of the information areas must be approximately 180 °, while the phase depth of the intermediate areas must be between 95 ° and 145 °. To achieve this phase depth, the geometry of the information structure will be different than that of the radiation reflecting information structure described above. It can be said that the geometric depths or heights of the information areas and intermediate areas for a radiation-transmissive recording medium are approximately twice greater than the depths or heights of the areas for a radiation-reflecting recording medium.

For example, in DE-PS 29 09 877 proposed an optical recording medium as a storage medium for other than video information and especially to use it as a storage medium, in which the user himself inscribes information can. It is important to think of information provided by one (Office) computer is delivered or from in a hospital X-rays taken. For this application the user receives a record carrier with a z. B. provided spiral so-called servo track is that over the entire recording medium surface extends.

When the information is written in by the user, the radial position of the writing spot in relation to the servo track is detected and readjusted using an optoelectronic servo system, so that the information is written into a spiral track with a constant gradient with great accuracy. The servo track is divided into a variety of sectors, e.g. B. 128 per revolution. Fig. 9 is a plan view of such a record carrier 50. The servo track is labeled 51 and the sectors are labeled 52 . Each sector consists of a track part 54 , in which the information can be written, and a sector address 53 , in which, among other things, the address of the associated track part 54 in z. B. is encoded in digital form in address areas. The address areas are separated from each other in the track direction by intermediate areas. The address areas can consist of pits pressed into the recording medium surface or of protrusions protruding beyond this surface.

According to the invention, the address areas consist of pits or humps with a first phase depth and the intermediate areas consist of pits or humps with a second phase depth, the second phase depth being smaller than the first phase depth, in the same way as for the information areas and the intermediate areas in FIG a recording medium is described with a video program. A tangential section through the sector addresses then looks as shown in FIG. 2. The sector addresses of all tracks preferably lie within the same circular sectors. In this case, a radial section through the address areas or through the intermediate areas looks as shown in FIG. 3 or FIG. 4.

The unwritten track parts 54 can consist of continuous grooves on which a layer of reflective material is applied, which, when exposed to suitable radiation, is subjected to an optically detectable change. For example, the layer consists of bismuth, in which information areas can be formed by melting.

The blank track parts can consist of V-shaped grooves. In order to be able to derive an optimal tracking signal by means of a “push pull” reading when writing in with these grooves, as can be seen from the above, these grooves must have a phase depth that is approximately 110 °. With "Central aperture" reading of the record carrier inscribed by the user, in which holes are thus made in the V-shaped grooves by melting, the groove parts between the holes will still give a small signal if these groove parts have a phase depth of 110 ° ( see Fig. 7). Therefore, the phase depth of the unwritten grooves is preferably selected to be approximately equal to 100 °, so that these grooves are virtually no longer "seen" during the "central aperture" reading of the recorded recording medium.

The invention is based on a round disc-shaped recording medium has been explained. they but can also be used with other record carriers, such as tape-shaped or cylindrical recording media, apply.

Claims (6)

1. Record carrier in which information is attached in an optically readable information structure, which consists of information areas arranged in information tracks, which are separated from one another in the track direction by intermediate areas, the information tracks being separated from one another by intermediate tracks, and wherein the information areas have a phase depth of approximately 180 ° which is almost constant over the entire recording medium, characterized in that the intermediate regions have a phase depth between 95 ° and 145 ° with respect to the intermediate tracks which is almost constant over the entire recording medium. 2. Record carrier according to claim 1 with a radiation reflecting information structure, characterized in that the phase depth of the intermediate areas has a value between approximately 100 ° and approximately 110 °, that the intermediate areas are essentially V-shaped are that the angle of inclination between the walls the intermediate areas and a normal a value on the record carrier in the range of 80 ° to 85 °.   3. Record carrier according to claim 2, the is designed with a helium-neon gas laser delivered readout bundle with a wavelength of about 633 nm to be read, characterized in that the track width is about 625 nm, and that the phase depth of the intermediate areas about 100 ° and the angle of inclination of the walls of the intermediate areas is about 84 °. 4. Record carrier according to claim 2, the is intended with one of an AlGaAs semiconductor diode laser delivered readout bundle with a wavelength to be read out between 780 and 860 nm, characterized in that that the track width the intermediate areas is about 625 nm, and that the phase depth of the intermediate areas 100 ° and the angle of inclination the walls of the intermediate areas is about 82 °. 5. Record carrier according to one of the preceding Claims made by a user in advance certain track parts of information are registered can, characterized in that information only in Sector addresses exist in which addresses are associated parts of the track that have not yet been written on Material included, are appropriate, the information areas or the intermediate areas in the sector addresses a phase depth of approximately 180 ° or a phase depth have between 95 ° and 145 °.   6. Record carrier according to claim 5, characterized in that the unwritten track parts are radiation reflecting and have a phase depth of approximately Have 100 °.